JP4322924B2 - Method and apparatus for performing inter-AN HRPD hard handoff - Google Patents

Description

  The present invention relates to a wireless communication system. More particularly, the present invention relates to performing HRPD (High Rate Packet Data) hard handoffs between ANs (Access Networks).

  Existing high rate packet data (HRPD) / 1XEV-DO (DO) systems function according to the interface standard developed by 3GPP2 / TIA. 3GPP2 represents 3rd Generation Partnership Project 2 (3rd Generation Partnership Project 2). 3GPP2 includes its web page, www. 3gpp2. com. TIA stands for Telecommunications Industry Association. TIA has its web page, www. tiaonline. You can contact us via org. An HRPD system typically employs an air interface that conforms to TIA-856, but its network architecture is built according to the TIA-878 standard or the TIA-1878 standard. Currently, these standards do not provide a hard handoff of active packet data sessions between ANs in an HRPD network.

  Moreover, these standards require that the HRPD packet data session be transitioned to the dormant state (sleep mode handoff) before being handed off to the target HRPD AN. FIG. 5 is an exemplary signaling flow diagram 700 illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to prior art signaling techniques. As shown in flow diagram 700, the source AT disconnects from the AT and establishes the packet data session to sleep before establishing a connection with the target AN. Additional signaling details can be found in TIA-1878. For example, Section 3.5.3 (indicating HRPD session release initiated by a source AN with an active A8 connection) or Section 3.7.1 Dormant Mode Handoff Section (Dormant Mode Handoff) (See network-initiated successful target-side signaling and session reactivation).

  Although the session is reactivated once the dormant session is successfully transferred to the target AN, prior art signaling approaches add significant delay to the handoff. Such a delay may not be acceptable for applications with strict QoS (Quality of Service) requirements, such as VoIP (Voice over Internet Protocol). Thus, this prior art approach can destroy data services and provide an inadequate user experience. Accordingly, a method and apparatus for performing inter-AN HRPD hard handoff that can reduce current handoff delay is desired.

  Various embodiments are described that address the need to reduce handoff delay associated with HRPD (High Rate Packet Data) / 1XEV-DO handoffs between ANs (Access Networks). The approach of the present disclosure allows an AT with an active packet data session to perform a hard handoff from the source AN to the target AN without having to sleep the data session. Unlike known hard handoff techniques with coordination by the mobile switching center (MSC) (see, eg, IOS A.S0013-B, section 3.17.5.10), the technique of the present disclosure uses the source AN Peer-to-peer signaling without MSC is used between the target AN, the source PCF, and the target PCF. For example, source side data session information is forwarded to the target peer of the source entity via new A13 messaging, reducing signaling between the source and target devices.

  The embodiments of the present disclosure can be more fully understood with reference to FIGS. FIG. 1 is a block diagram of a wireless communication system 100 according to an embodiment for TIA-878 of the present invention, and FIG. 2 is a block diagram of a wireless communication system 200 according to an embodiment for TIA-1878 of the present invention. Communication systems 100 and 200 are well-known high rate packet data (HRPD) / 1XEV-DO (DO) code division multiple access (CDMA) systems, suitably modified to implement the present invention.

  1 and 2 do not show all of the network equipment necessary for the respective systems 100 and 200 to operate, but system components and logical entities that are particularly relevant to the description of embodiments of the present invention. Those skilled in the art will appreciate that only is shown. Specifically, the network equipment of the system 100 includes wireless connection networks (RAN) 125 and 126, access networks (AN) 121 and 122, packet control functions (PCF) 131 and 132, a packet data serving node (PDSN) 141, and Includes components such as an Internet Protocol (IP) network 151. Similarly, the network equipment of the system 200 includes access network (AN) 221 and 222, packet control function (PCF) 231 and 232, packet data serving node (PDSN) 141, and Internet Protocol (IP) network 151, and the like. including. In general, RAN, AN, PCF, PDSN, and IP networks are well known to those skilled in the art. For example, it is well known that the RAN comprises AN and PCF, and that the PCF comprises components such as a processing unit and a PCF network interface. In addition, since it is well known that the AN comprises components such as a controller and an access network transceiver system (ANTS), none of them are shown in detail in FIGS.

  In FIG. 2, the PCFs 231 and 232 are shown to include processing units 235 and 236 and PCF network interfaces 237 and 238. In general, components such as processing units and network interfaces are well known. For example, it is well known that a processing unit comprises basic components such as, but not limited to, one or more of a microprocessor, a microcontroller, a memory device, and a logic circuit. Typically, such components are one of algorithms and protocols expressed using one or more of advanced design languages or descriptions, computer instructions, messaging / signaling flow diagrams, call flow diagrams, and logic flow diagrams. Or is adapted to implement both.

  Thus, given one or more of an algorithm, logic flow, messaging / signaling flow, call flow, and protocol specification, those skilled in the art can use it to implement a PCF that performs the given logic. Many possible design and development methods are recognized. Accordingly, PCFs 231 and 232 represent known PCFs that are adapted to implement multiple embodiments of the present invention in accordance with the description herein. Similarly, RANs 125, 126 represent known RANs that are adapted to implement multiple embodiments of the invention in accordance with the description herein.

  The RANs 125 and 126 and the ANs 221 and 222 use the air interfaces 111 and 112 for communication with the remote unit 101. The air interfaces 111 and 112 are HRPD / 1xEV-DO air interfaces according to TIA-856. As referred to throughout this application, the term HRPD / 1xEV-DO refers to a remote unit as an access terminal (AT). It is well known to those skilled in the art that the remote unit / AT platform typically comprises devices such as mobile phones, computers, personal digital assistants, gaming devices and the like. Specifically, AT 101 comprises component devices (not shown) such as processors and transceivers, both well known to those skilled in the art.

Referring to FIG. 1, the relevant aspects of operation of an embodiment for TIA-878 are shown. Source RAN 125 with source AN 121 and source PCF 131 supports already active HRPD packet data sessions to AT 101. For illustrative purposes, assume that the AT 101 has found a strong neighbor cell. Accordingly, AN 121 receives a route update message indicating the c-end off-target from AT 101. Again it is assumed for illustrative purposes, not the Ha-end off-target this is within RAN125, to be within the RAN126. Thus, while continuing to support active sessions, the AN 121 determines that the AT 101 should handoff to the RAN 126 and sends a handoff request for the AT 101 to the target RAN 126. When this handoff request is transmitted, the AT 101 can be handed off without changing the session to the sleep mode, that is, without dropping the session (when the session is disconnected, the packet data call Need to be re-established). In some embodiments, this handoff request includes the following information: AT 101 mobile node identifier, handoff target sector identifier, target channel information, serving PDSN Internet Protocol (IP) address (ie, IP address of PDSN 141). ), Source access network identifier, AT 101 source AN UATI, HRPD packet data session state information record (may include AT 101 source RAN UATI used by target RAN 126 in receiving AT 101 start signaling), security Layer packet, anchor PDSN address, anchor PP address, and air interface version indicator. In other embodiments, a subset of this information may or may not be communicated during a handoff request.

  The AN 122 of the RAN 126 receives the AT 101 handoff request and responds with a handoff request acknowledgment indicating that the handoff request has been accepted by the target RAN 126 (assuming it is accepted for purposes of illustration, but of course , May be rejected). In some embodiments, the handoff request acknowledgment also includes handoff related information, such as at least part of the mobile node identifier of AT101, the handoff target sector identifier, and a traffic channel assignment message transmitted to AT101. It is. In other embodiments, upon handoff request acknowledgment, a subset of this information may or may not be communicated.

  The AN 121 of the RAN 125 receives a handoff request acknowledgment indicating that the handoff request has been accepted by the target RAN. Since the AT 101 is scheduled to handoff to the target RAN 126, the PCF 131 of the RAN 125 may request the PDSN 141 to interrupt data transmission to the source RAN 125 in that session. Also, after receiving the handoff request acknowledgment, the AN 121 sends traffic channel assignment signaling to the AT 101 that assigns a new active set supported at least in part by the target RAN 126. For this reason, the AT 101 can perform handoff without transition of the HRPD packet data session to the sleep mode, that is, without disconnection. Further, the traffic channel assignment signaling transmitted to the AT 101 may include a portion transmitted to the AN 121 via a handoff request acknowledgment or other signaling means.

  In response to traffic channel assignment signaling, target AN 122 receives traffic channel completion signaling from AT 101. Basically, traffic channel completion signaling serves to acknowledge traffic channel assignment signaling received by AT 101. The target AN 122 also decodes the traffic channel completion signaling using the AT 101 unicast access terminal identifier (UATI) used in the source RAN 125. In response to the traffic channel completion signaling, the target AN 122 sends a new UATI assignment to the AT 101 and receives the UATI completion signaling in an acknowledgment. In addition to signaling with the AT 101, the RAN 126 (ie, PCF 132) sends a request to the PDSN 141 to establish a data connection for the AT 101 session, indicating an indication that the data connection is accepted. Receive. Thus, AN 122 and PCF 132 can support AT 101's active HRPD packet data session after AT 101's handoff, without requiring the session to be handed off in dormant mode, ie, disconnecting.

  AN 122 also sends handoff status signaling to RAN 125 indicating that AT 101 has successfully handed off to target RAN 126. In response to receiving this handoff state signaling, the RAN 125 sends an indication to the PDSN 141 to release the resources that supported the AT 101 data session via the source RAN 125.

Referring to FIG. 2, the relevant aspects of operation of the embodiment for TIA-1878 are shown. Source AN 221 and source PCF 231 (ie, PCF processing unit 235 via PCF network interface 237) support already active HRPD packet data sessions to AT 101. For illustrative purposes, assume that the AT 101 has found a strong neighbor cell. Therefore, AN221 receives a route update message indicating the c-end off-target from AT 101. Again it is assumed for illustrative purposes, not the Ha-end off-target this is within AN221, to be within the AN222. Thus, while continuing to support active sessions, AN 221 determines that AT 101 should handoff to AN 222 and sends handoff required signaling to PCF 231.

  While continuing to support active sessions, the PCF processing unit 235 receives handoff required signaling via the PCF network interface 237. This signaling indicates a handoff of the AT 101 to the target AN 222, which allows the AT 101 to hand off without putting the data session into sleep mode, i.e. without disconnecting. In some embodiments, this handoff required signaling includes the following information: AT identifier, handoff target sector identifier, signaling correlation identifier, target channel information, and air interface version indicator. In other embodiments, a subset of this information may be conveyed during handoff required signaling.

  After determining that the target AN 222 is supported by the target PCF 232, the PCF processing unit 235 transmits a handoff request of the AT 101 to the PCF 232 via the PCF network interface 237. When this handoff request is transmitted, the AT 101 can be handed off without changing the session to the sleep mode, that is, without disconnecting the session. In some embodiments, this handoff request includes the following information: AT 101 mobile node identifier, handoff target sector identifier, target channel information, serving PDSN Internet Protocol (IP) address (ie, IP address of PDSN 141). ), Source access network identifier, AT 101 source AN UATI, HRPD packet data session state information record (may include AT 101 source AN UATI used by target AN 222 in acquiring AT 101), security layer Packet, anchor PDSN address, anchor PP address, and air interface version indicator. In other embodiments, a subset of this information may or may not be communicated during a handoff request.

  The PCF processing unit 236 receives the handoff request (ie, “PCF handoff request”) via the PCF network interface 238 and transmits the AT handoff request of the AT 101 to the AN 222 based on the PCF handoff request. In some embodiments, this AN handoff request includes the following information: AT identifier, signaling correlation identifier, handoff target sector identifier, AT 101 source AN UATI, HRPD packet data session state information record (AT101) (May include source AN UATI of AT 101, used by target AN 222 in acquisition), A14-specific indicator, target channel information, and air interface version indicator. In other embodiments, this subset of information is conveyed instead. In response, the PCF processing unit 236 receives an indication from the target AN 222 via the PCF network interface 238 that the target AN has accepted the AT 101 handoff. In some embodiments, this indication that the target AN has accepted the handoff includes a signaling correlation identifier and at least some of the air interface traffic channel assignment messages sent to the AT 101. However, in other embodiments, during such handoff acceptance indication, a subset of this information may or may not be communicated.

  In response, the PCF processing unit 236 sends a PCF handoff request acknowledgment to the source PCF 231 via the PCF network interface 238 indicating that the previous PCF handoff request has been accepted by the PCF 232. In some embodiments, this PCF handoff request acknowledgment includes at least a portion of the mobile node identifier of AT 101, the handoff target sector identifier, and an air interface traffic channel assignment message sent to AT 101 (eg, , As received at handoff acceptance indication). However, in other embodiments, this subset of information may be communicated instead (including the absence of information).

  In response to receiving the PCF handoff request acknowledgment, the PCF processing unit 235 sends a handoff required acknowledgment indicating to the source AN 221 via the PCF network interface 237 that the handoff of the AT 101 to the target AN 222 has been accepted by the PCF 232. Send. In some embodiments, the PCF handoff request acknowledgment includes at least a portion of an AT identifier, a signaling correlation identifier, and a traffic channel assignment message sent to the AT 101 (eg, a PCF handoff request acknowledgment). Received). However, in other embodiments, this subset of information may be communicated instead (including the absence of information).

  Upon receiving an indication that the handoff to the target AN 222 of the AT 101 has been accepted by the PCF 232, the source AN 221 requests the PCF 231 to suspend data transmission to itself in the data session. Upon receiving this request, if flow control is supported, the PCF processing unit 235 requests the PDSN 141 via the PCF network interface 237 to interrupt data transmission to itself in the data session.

  After the AT 101 initiates communication with the target AN 222, the PCF processing unit 236 receives the AT 101 UATI request from the target AN 222 via the PCF network interface 238. In response to this request, the PCF processing unit 236 sends the AT 101 UATI assignment to the target AN 222 via the PCF network interface 238.

  At some point after receiving the start handoff request from the source PCF 231, the PCF processing unit 236 sends a request for establishing a data connection for the AT 101 session to the PDSN 141 via the PCF network interface 238, and the data connection Receive indications as accepted. Thus, AN 222 and PCF 232 can support an active HRPD packet data session for AT 101 without requiring the session to be handed off in dormant mode after AT 101 handoff, i.e., without disconnecting.

  The target PCF 232 also sends handoff state signaling to the source PCF 231 indicating that the AT 101 has successfully handed off to the target AN 222. In response to receiving this handoff status signaling, the PCF processing unit 235 sends a request to the source AN 221 via the PCF network interface 237 to disconnect the data connection supporting the session between the source PCF 231 and the source AN 221. At the same time, a request for releasing the A10 connection with the PCF 231 in the session is transmitted to the PDSN 141.

  Thus, several embodiments have been presented that address the need to reduce handoff delays associated with inter-AN HRPD / 1XEV-DO hard handoffs. According to the approach disclosed above and described in more detail below, an AT with an active packet data session is able to perform a hard transfer from a source AN to a target AN without having to dormantize the data session, i.e., without having to disconnect. A handoff can be performed.

  3A and 3B are exemplary signaling flow diagrams illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to an embodiment for TIA-878 of the present invention. The following is a detailed description of a representative signaling flow timeline labeled in the rightmost column of FIGS. 3A and 3B (message definitions are found later in the detailed description of the invention herein below). )

a. Active packet data session is supported by AT, source AN, source PCF and PDSN (traffic channel and neighbor list assigned to AT by AN, A8 / A10 bearer connection established, AT and PDSN There is a PPP connection).
b. The AT sends a route update message to the source AN indicating strong neighbors that are not under the domain of the source AN.
c. If it determines that the target cell is in the domain of another AN, the source AN sends an A13-handoff request to the target AN that supports the target cell. The source AN has AT session information, target cell information, source PCF ANID, and the address of the PDSN that currently supports the call in the message. If fast handoff is supported, the source AN has an anchor PDSN address and an anchor PP address. The message also includes the version of the air interface used at the source, so the target formats the air interface TCA message accordingly. The source AN starts timer _TA13-horeq .
d. The target AN sends an A9-setup-A8 message to the target PCF to establish an A8 connection for the call and starts a timer T _A8-setup . If inter-PDSN HHO is required, the target PCF may initiate a fast handoff procedure.
e. The target PCF responds by sending an A9-Connect-A8 message to the target AN. The target AN stops timer T _A8-setup .
f. The target AN sends to the source AN an A13-handoff request acknowledgment that acknowledges the handoff request from the target network. This message includes an air interface traffic channel assignment message formatted according to the air interface version used in the source network. Upon receipt of the message, the source AN stops timer _TA13-horeq .
g. The source AN sends an A9-Al-disconnect message to the source PCF, requesting the source PCF to stop transmitting packet data to the AN, and starts a timer T _ald9 . If flow control is supported by the PDSN of the connection, the source PCF sends a flow control Xoff signal in the same row to the PDSN, and stops data transmission to the source PCF.
h. In response to the source AN, the source PCF responds to the source AN with an A9-Al disconnect acknowledgment message. The source AN stops timer T _Ald9 .
i. The source AN sends a traffic channel assignment message to the AT that includes a new active set that includes the target cell. This message may be sent at any time after step f.
j. The AT responds to the target AN with a traffic channel completion message. This step may be sent at any time after step f.
k. This AN sends a UATI assignment message and assigns the UATI to the AT.
l. The AT sends a UATI completion message and notifies the AN that the AT has received a UATI assignment message. If necessary, after this step, the target AN may initiate one or more of a session negotiation procedure and a termination authentication procedure. If a failure occurs, an A13-handoff status message may be sent indicating failure.
m. The target BS sends an A9-AL connection message to the target PCF and starts timer T _alk9 .
n. This step occurs if the fast handoff procedure is not started in step d. This PCF selects the PDSN transmitted by the source AN in the A13-handoff request. If the target PCF is unable to connect to the source PDSN, the target PCF selects an alternative PDSN using a PDSN selection algorithm. The target PCF sends an A11 registration request message to the PDSN. This message includes MEI indication in CVSE, non-zero lifetime value, accounting data (A10 connection setup and possibly active start airlink record), and the source PCF's ANID (PANID) and target PCF in NVSE ANID (CANID) is included. The target PCF starts a timer T _regreq .
o. The PDSN validates the A11 registration request and accepts the connection by returning an A11 registration response message with an acceptance indication and a lifetime field set to the configured T _rp value. The target PCF stops timer T _regreq .
p. In response to the A9-AL connection message, the target PCF sends an A9-AL connection acknowledgment message and stops timer T _alk9 .
q. If the target PCF is unable to connect to the source PDSN, ie, the PDSN that supported the call prior to handoff, a PPP connection is established and the MIP registration procedure is performed (if supported).

Here, the HRPD packet data session becomes active in the target cell, and packet data is exchanged between the AT and the PDSN.
r. The target AN sends an A13-handoff status message with a cause value to the source AN, indicating successful completion of a hard handoff to the target network.
s. The AN sends an A9-Release-A8 message with the cause value set to “Hard Handoff Complete” to the PCF, requesting the PCF to release the associated dedicated resources. The AN starts timer T _rel9 . The source PCF stops timer T _discon9 .
t. The source PCF sends to the PDSN an A11 registration request message with a lifetime set to 0 and an accounting record. The PCF starts timer T _regreq .
u. The PDSN sends an A11 registration response message to the source PCF. The source PCF closes the source A10 connection to the AT and stops the timer T _regreq .
v. The source PCF responds to the A9-release-A8 message with an A9-release-A8 completion message. The source AN stops timer T _rel9 .

  4A and 4B are representative signaling flow diagrams illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to an embodiment for TIA-1878 of the present invention. The following is a detailed description of a representative signaling flow timeline labeled in the rightmost column of FIGS. 4A and 4B.

a. Active packet data session is supported by AT, source AN, source PCF and PDSN (traffic channel and neighbor list assigned to AT by AN, A8 / A10 bearer connection established, AT and PDSN There is a PPP connection).
b. The AT sends a route update message to the source AN indicating strong neighbors that are not under the domain of the source AN.
c. The source AN sends an A14-Handoff Required message to the source PCF with the target cell pilot information (pilot). The source AN starts timer _TA14-horeq .
d. If it determines that the target cell is in the domain of another PCF (the source PCF maintains a neighbor cell for the AN mapping information), the source PCF will send an A− to the target PCF that supports the target AN. Send 13 handoff request. The source PCF has the AT session information, its own ANID, target cell information, and the address of the PDSN that currently supports the call in the message. If fast handoff is supported, the source PCF has an anchor PDSN address and an anchor PP address. This message also includes the air interface version used at the source so that the target can format the air interface TCA message accordingly. The source PCF starts timer _TA13-horeq .
e. The target PCF sends an A14-handoff request message to the target AN requesting an AT handoff to the target cell. The target PCF starts timer _TA14-horeq .
f. Upon receiving the A14-Handoff Request message at the target AN, if the handoff can be supported, the target AN sends an A9-Setup-A8 message to the target PCF to establish an A8 connection for the call and T _A8-setup Start the timer. If inter-PDSN HHO is required, the target PCF may initiate a fast handoff procedure.
g. The target PCF responds by sending an A9-Connect-A8 message to the target AN. The target AN stops timer T _A8-setup .
h. The target AN sends an A14-Handoff Request Acknowledge message to the target PCF, indicating that it accepts the handoff. This message includes an air interface traffic channel assignment message formatted according to the air interface version used in the source network. The target PCF stops timer _TA14-horeq .
i. The target PCF sends an A13-handoff request acknowledgment to the source PCF and acknowledges the handoff request from the source network. This message includes an air interface traffic channel assignment message formatted according to the air interface version used in the source network. Upon receipt of the message, the source PCF stops timer _TA13-horeq .
j. The source PCF sends an A14-Handoff Required Acknowledgment message to the source AN, including a cause value indicating that the handoff request has been accepted and an air interface traffic channel assignment message. The source AN stops timer TA _A14-horeq .
k. The source AN sends an A9-Al-disconnect message to the source PCF, requesting the source PCF to stop transmitting packet data to the AN, and starts a timer T _Ald9 . If flow control is supported by the PDSN of the connection, the source PCF sends a flow control Xoff signal in the same row to the PDSN, and stops data transmission to the source PCF.
l. The source PCF responds to the source AN with an A9-Al disconnect acknowledgment message. The source AN stops timer T _Ald9 .
m. The source AN sends a traffic channel assignment message to the AT that includes a new active set that includes the target cell. This step may occur at any time after step j.
n. The AT responds to the target AN with a traffic channel completion message.
o. The target AN sends an A14-UATI request message to the target PCF, requesting the AT to assign a UATI.
p. The target PCF allocates a UATI from its UATI pool to the AT, transmits an A14-UATI allocation message including the allocated UATI, and starts a timer T _{14-UATI-Assign} .
q. The AN sends a UATI assignment message and assigns a UATI to the AT.
r. The AT sends a UATI completion message and notifies the AN that the AT has received a UATI assignment message. If necessary, after this step, the target AN / PCF may initiate one or more of a session negotiation procedure and a termination authentication procedure. If a failure has occurred, an A13-handoff status message indicating the type of failure may be sent.
s. Upon receiving a UATI completion message from the AT, the AN sends an A14-UATI completion message to the PCF to notify the PCF of successful completion of the UATI assignment. The AN starts timer _{T14-UATI-Comp} . Upon receiving the A14-UATI completion message, the PCF stops timer _{T14-UATI-Assign} .
t. The PCF sends an A14-UATI completion acknowledgment message as an acknowledgment to the AN. The AN stops timer _{T14-UATI-Comp} .
u. The target BS may send an A9-AL connection message to the target PCF, and the target BS starts timer T _alk9 . Since the PCF already knows that the AT has reached the target BS, the connection / connection acknowledgment message may be arbitrary.
v. This step occurs if the fast handoff procedure is not started at step f. The PCF selects the PDSN transmitted by the source PCF in the A13-handoff request. If the target PCF is unable to connect to the source PDSN, the target PCF selects an alternative PDSN using a PDSN selection algorithm. The target PCF sends an A11 registration request message to the PDSN. This message includes MEI indication in CVSE, non-zero lifetime value, accounting data (A10 connection setup and possibly active start airlink record), and the source PCF's ANID (PANID) and target PCF in NVSE ANID (CANID) is included. The target PCF starts a timer T _regreq .
w. The PDSN validates the A11 registration request and accepts the connection by returning an A11 registration response message with an acceptance indication and a lifetime field set to the configured T _rp value. The target PCF stops timer T _regreq .
x. In response to the A9-AL connection message, the target PCF sends an A9-AL connection acknowledgment message and stops timer T _alk9 .
y. If the target PCF is unable to connect to the source PDSN, ie, the PDSN that supported the call prior to handoff, a PPP connection is established and the MIP registration procedure is performed (if supported).

Here, the HRPD packet data session becomes active in the target cell, and packet data is exchanged between the AT and the PDSN.
z. The target PCF sends an A13-handoff status message with a cause value to the source PCF, indicating successful completion of a hard handoff to the target network. In the case of a hard handoff failure, this message may be sent earlier.
aa. After receiving the A13-Handoff Status message, the PCF sends an A9-Disconnect-A8 message with the cause value set to “Hard Handoff Complete” to the AN and starts timer T _discon9 . This message may be sent at any time after step n.
bb. The source AN sends an A9-Release-A8 message with the cause value set to “hard handoff complete” to the PCF, requesting the PCF to release the associated dedicated resources. The source AN starts timer T _rel9 . The source PCF stops timer T _discon9 .
cc. The source PCF sends to the PDSN an A11 registration request message with a lifetime set to 0 and an active stop AL record. The PCF starts timer T _regreq .
dd. The PDSN sends an A11 registration response message to the source PCF. The source PCF closes the source A10 connection to the AT and stops the timer T _regreq .
ee. The source PCF responds to the A9-release-A8 message with an A9-release-A8 completion message. The AN stops timer T _rel9 .

  In the representative signaling flow diagrams of FIGS. 4A and 4B, both A13 and A14 signaling are shown. However, if the source AN and the target AN are served by the same PCF (ie, the source PCF and the target PCF are the same single PCF), signaling such as A13 signaling between the source PCF and the target PCF is not Does not occur.

  In the above representative signaling flow diagrams (FIGS. 3A, 3B, 4A, 4B), A13 handoff request, A13-handoff request acknowledgment, A13-handoff state, A14-handoff required, A14-handoff required acknowledgment, A14- Several new messages are described, such as handoff requests and A14-handoff request acknowledgments. Representative definitions of these messages are provided below to improve understanding and to illustrate specific embodiments that may be implemented. However, one of ordinary skill in the art appreciates that various modifications and changes can be made to the specific embodiment described below without departing from the spirit and scope of the invention.

A13 message definition [A13-Handoff request]
This message is sent from the source PCF to the target PCF to request to request an AT hard handoff.

This IE contains the mobile identifier of the AT for which a hard handoff is requested.
This information element contains the target cell pilot and pilot strength information. There may be multiple instances of this element.
This IE contains the IP address of the PDSN that supports the call in the source network.
This element contains the ANID of the source PCF.
This IE contains a session state information record used in the source network. Multiple copies of this information element may be included. If an attribute is not included in the session state information record, the target AN assumes that the missing attribute has a default value (specified for each attribute in each protocol).
These IEs are included if fast handoff is supported.
This IE contains the version of the air interface used at the source AN.

  The following table shows the bitmap layout of the A13-handoff request message.

[A13-Handoff request acknowledgment]
This message is sent from the target PCF to the source PCF to acknowledge the AT's hard handoff request.

a. This IE contains the mobile identifier of the AT for which a hard handoff is requested.
b.
c. This information element includes the target network sector ID.
d. This information element indicates whether the hard handoff request has been accepted or rejected by the target network.
e. This information element contains an air interface TCA message that is encoded into the version of the air interface used at the source and is included when the handoff request is accepted by the target network.

  The following table shows the bitmap layout of the A13-Handoff Request Acknowledgment message.

[A13-Handoff state]
This message is sent from the target PCF to the source PCF to indicate to the target AN whether or not the AT hard handoff has been completed.

a. This information element indicates to the target network whether or not a hard handoff has been completed.
The following table shows the bitmap layout of the A13-Handoff Status message.

A14 message definition [A14-Handoff required]
This message is sent from the source AN to the source PCF to request an AT hard handoff from the new AN.

a. If this information element is included in this message, the value of this information element is returned by the corresponding information element in the A14-Handoff Accept message sent in response to this message.
b. This information element is used to identify the sector to handoff.
c. This information element includes target cell pilot and pilot strength information. There may be multiple instances of this element.
d. This IE contains the version of the air interface used at the source AN.

  The following table shows the bitmap layout of the A14-Handoff Required message.

[A14-Handoff required acknowledgment]
This message is sent from the source PCF to the source AN to acknowledge the A14-Handoff Required message.

a. This information element is included only if it was also included in the A14-session information update message. This information element is set to the value received in the A14-session information update message.
b. This information element indicates whether the handoff request has been accepted.
c. This information element contains an air interface TCA message that is encoded into the version of the air interface used at the source and is included when the handoff request is accepted by the target network.

  The following table shows the bitmap layout of the A14-session information update acknowledgment message.

[A14-Handoff request]
This message is sent from the target PCF to the target AN to request a hard handoff.

a. If this information element is included in this message, the value of this information element is returned by the corresponding information element in the A14-Handoff Request Acknowledgment message sent in response to this message.
b. This information element is included when the PCF indicates an accurate paging area. If this information element is included, the AT is paged to at least all sectors shown in this list.
c. Multiple copies of this information element may be included.
d. This information element includes target cell pilot and pilot strength information. There may be multiple instances of this element.
e. This IE contains the air interface version used at the source AN.

  The following table shows the bitmap layout of the A14-request request message.

[A14-Handoff request acknowledgment]
This message is sent from the target AN to the target PCF to acknowledge the hard handoff request.

b. This information element indicates whether the c hard handoff request was accepted or rejected by the target AN.
c. This information element contains an air interface TCA message that is encoded into the version of the air interface used at the source and is included when the handoff request is accepted by the target network.

  The following table shows the bitmap layout of the A14-Handoff Request Acknowledgment message.

A13 Information element definition [Information element identifier]
This table includes information element identifier (IEI) encoding, where one element is distinguished from another. This table also includes references to the clauses where element coding can be found.

[A13 message type]
The A13 message type information element is used to indicate the type of message on the A13 interface.

[Cause]
This information element is used to indicate the reason for the occurrence of a specific event and is encoded as follows.

Length: This field contains the number of octets following this field as a binary number in this information element.
Cause value: This field is set to a value in the following range:

[Anchor PDSN address]
This element contains the A11 interface IPv4 address of the anchor PDSN address and is used for fast handoff.

Length: This field indicates the number of octets following this length field in this element.
Anchor P-P address: This field contains the P-P interface IPv4 address of the anchor PDSN. See IS-835-C.

[Anchor PP address]
This element contains the P-P interface IPv4 address of the anchor PDSN in fast handoff.

Length: This field indicates the number of octets following this length field in this element.
Anchor P-P address: This field contains the P-P interface IPv4 address of the anchor PDSN. See IS-835-C.

[Target channel information]
This information element includes target cell pilot and pilot strength information.

Length: This field contains the number of octets following this field as a binary number in this information element.
Channel: This field contains the channel corresponding to the target pilot and is encoded as specified in the TIA-856 path update message.
Pilot strength: This field contains the strength of the pilot and is encoded as specified in the TIA-856 path update message.

[AI version]
This information element indicates the AI version supported by the source network.

Length: This field contains the number of octets following this field as a binary number in this information element.
Channel: This field indicates the AI used at the source, so the target can determine how to format the traffic channel assignment message. This field is encoded as 1: TIA-856-0, 2: TIA-856-A.

[TCA BLOB]
This information element is provided for each air interface version used in the source network (e.g., section 6.6.6.2.2 of TIA-856 or 9.7.6.2.2 of TIA-856-A). A TIA-856 traffic channel assignment message, formatted as per clause).

TCA Information Bit-Exact Length-Octet Count: This field contains the total number of octets in the TCA Information Content field, expressed as a binary number.
TCA Information Bits Exact Length-Fill Bits: This field contains a binary number that indicates the number of fill bits contained in the last used octet for the TCA information content field.
TCA information content: The TCA information content field is encoded every [TIA-856 for each version number supported by the source AN].
Nth fill bit-if necessary (octet k): If the "TCA information: bit exact length-fill bit" field contains a non-zero value, the number of fill bits indicated is set to "0" and the TCA information Occupies the low order bit position of the last used octet for the content field.
Revision A version 9.6.6.6.16.6 shows the fields that need to be transmitted.

A14 Information element definition [Information element identifier]
This table includes information element identifier (IEI) encoding, where one element is distinguished from another. This table also includes references to the clauses where element coding can be found.

[A14 message type]
The A14 message type information element is used to indicate the type of message on the A14 interface.

[Cause]
This information element is used to indicate the reason for the occurrence of a specific event and is encoded as follows.

Length: This field contains the number of octets following this field as a binary number in this information element.
Cause value: This field is set to a value in the following range:

[Mobile identity (MN ID)]
This information element is used to provide the mobile node identification (MN ID) of the AT.

Length: This field contains the number of octets following this field as a binary number in this information element.

1 is a block diagram of a wireless communication system according to an embodiment for TIA-878 of the present invention. FIG. 1 is a block diagram of a wireless communication system according to an embodiment for TIA-1878 of the present invention. FIG. FIG. 9 is an exemplary signaling flow diagram illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to an embodiment for TIA-878 of the present invention. FIG. 9 is an exemplary signaling flow diagram illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to an embodiment for TIA-878 of the present invention. FIG. 9 is an exemplary signaling flow diagram illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to an embodiment for TIA-878 of the present invention. FIG. 9 is an exemplary signaling flow diagram illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to an embodiment for TIA-878 of the present invention. FIG. 2 is a representative signaling flow diagram illustrating an access terminal (AT) having an active HRPD packet data session handing off from a source AN to a target AN, according to prior art signaling techniques.

Claims (10)

A method for performing a hard handoff of an access terminal (AT) between a source high rate packet data (HRPD) radio access network (RAN) and a target HRPD RAN comprising:
A session support process in which the source RAN supports an AT active HRPD packet data session;
During the session support process, the AT determines that the source RAN determines to handoff to the target RAN;
A handoff request transmission step in which the source RAN transmits a handoff request of the AT to the target RAN after the session support step is continued and after the handoff determination step;
Traffic channel assignment signaling that assigns the AT a new active set supported at least in part by the target RAN to allow the AT to handoff without transitioning or disconnecting the HRPD packet data session to sleep mode A channel assignment transmission step in which the source RAN transmits the AT to the AT. Handoff determining step The method of claim 1 including the step of receiving a route update message indicating Ruha command off-target put in the target RAN source RAN from AT. A method for performing a hard handoff of an access terminal (AT) between a source high rate packet data (HRPD) radio access network (RAN) and a target HRPD RAN comprising:
Handoff request that the target RAN receives an AT handoff request from the source RAN with the session to allow the AT to handoff without transitioning or disconnecting the active HRPD packet data session in the source RAN to dormant mode Receiving process;
A channel completion receiving step in which the target RAN receives traffic channel completion signaling from the AT;
A UATI assignment transmission step in which the target RAN sends an AT unicast access terminal identifier (UATI) assignment to the AT in response to traffic channel completion signaling;
A session support step for supporting the same HRPD packet data session of an AT in a mode in which the target RAN is active. The target RAN sending a request to establish a data connection for the session to a packet data serving node (PDSN) supporting the session;
Receiving the indication that a data connection is accepted from a target RAN from a PDSN supporting the session. Perform a hard handoff of the access terminal (AT) between the source high rate packet data (HRPD) access network (AN) supported by the source packet control function (PCF) and the target HRPD AN supported by the target PCF A method for
A session support process in which the source PCF supports an AT active HRPD packet data session;
The source PCF receives from the source AN during the session support process, handoff required signaling indicating the AT's handoff to the target AN, allowing the AT to handoff without transitioning to or disconnecting from the session's sleep mode. A handoff required receiving process,
After determining that the target AN is supported by the target PCF, the source PCF transmits an AT handoff request to the target PCF;
A disconnect request transmission step in which the source PCF transmits to the source AN a request to disconnect the data connection supporting the same session between the source PCF and the source AN;
A release request transmitting step in which a source PCF transmits a request to release resources for the session to a packet data serving node (PDSN) supporting the session. Source high rate packet data (HRPD) access network (AN) supported by the source PCF and target HRPD supported by the target PCF
A method for performing a hard handoff of an access terminal (AT) with an AN, comprising:
PCF handoff request reception where the target PCF receives the PCF handoff request of the AT with the session from the source PCF to allow the AT to handoff without transitioning or disconnecting the active HRPD packet data session to sleep mode Process,
An AN handoff request transmission step in which the target PCF transmits an AN handoff request to the target AN based on the received PCF handoff request of the AT;
An acceptance indication receiving step in which the target PCF receives an indication from the target AN that the target AN has accepted the AT handoff;
A PCF handoff request acknowledgment sending step in which the target PCF sends a PCF handoff request acknowledgment to the source PCF indicating that the PCF handoff request has been accepted by the target PCF;
A UATI request receiving step in which the target PCF receives a request for a unicast access terminal identifier (UATI) of the AT from the target AN;
A UATI assignment transmission step in which the target PCF sends an AT UATI assignment to the target AN;
A connection establishment request transmission step in which the target PCF transmits a request for establishing a data connection of the session to a packet data serving node (PDSN) supporting the session;
A session support step for supporting the same HRPD packet data session of the AT in a mode in which the target PCF is active. A source HRPD RAN for performing a hard handoff of an access terminal (AT) to a target high rate packet data (HRPD) radio access network (RAN),
An access network (AN);
A packet control function (PCF) that is communicably connected to the AN;
AN and the PCF and the support to Turkey an active HRPD packet data session of the AT,
AN during the continuation of the support for the active session, AT is the Turkey be determined that the handoff to the target RAN and,
AN during continued support the active session, and, after determining that the AT to handoff, and Turkey to send a handoff request of AT to the target RAN and,
The AN allocates a new active set to the AT that is supported at least in part by the target RAN to allow the AT to handoff without transitioning or disconnecting the HRPD packet data session to sleep mode. source HRPD RAN consisting Turkey Toto to send channel allocation signaled to AT. A target HRPD RAN for performing a hard handoff from an access terminal (AT) source high rate packet data (HRPD) radio access network (RAN),
An access network (AN);
A packet control function (PCF) that is communicably connected to the AN;
AN, to AT without transition or cut into sleep mode active HRPD packet data session makes it possible to hand-off, and Turkey to receive the handoff request AT with the session from the source RAN and,
The AN and Turkey to receive the traffic channel completion signaling from AT,
The AN and Turkey to send the assignment of the unicast access terminal identifier of the AT in response to the traffic channel complete signaling (UATI) to AT,
AN and PCF is the same HRPD packet data session of AT in the active mode from the support to Turkey Toto target HRPD RAN. To perform a hard handoff of the access terminal (AT) from the source high rate packet data (HRPD) access network (AN) supported by the source packet control function (PCF) to the target HRPD AN supported by the target PCF Source PCF,
And P CF network interface that sends and receives the source AN, the target PCF and the packet data serving node (PDSN) signaling,
A processing unit communicably connected to the PCF network interface;
The processing unit is
Via the PCF network interface supports active HRPD packet data session AT,
Handoff required signaling indicating the handoff to the target AN of the AT, allowing the AT to handoff without transitioning to or disconnecting from the sleep mode of the session, and the PCF network interface while continuing to support the active session. It received from the source AN via,
After the determination of the target AN is supported by the target PCF, and sent to the target PCF handoff request AT via the PCF network interface, and,
The source PCF and between the source AN, source a request to disconnect the data connection that supports the session consists of Turkey Toto be transmitted to the source AN via the PCF network interface PCF. To perform a hard handoff of the access terminal (AT) from the source high rate packet data (HRPD) access network (AN) supported by the source packet control function (PCF) to the target HRPD AN supported by the target PCF Target PCF,
And P CF network interface target AN, send and receive signaling and source PCF and packet data serving node (PDSN),
A processing unit communicably connected to the PCF network interface;
The processing unit is
For AT without an active transition or cut into sleep mode of HRPD packet data session allows handoff receives the PCF handoff request AT with the session from the source PCF via the PCF network interface,
Based on the received AT PCF handoff request, sends an AN handoff request to the target AN via the PCF network interface;
An indication of the target AN has received the handoff of AT received from the target AN through the PCF network interface,
PCF handoff request is the PCF handoff request acknowledgment that was accepted by target PCF sends to the source PCF via the PCF network interface,
Receiving an AT unicast access terminal identifier (UATI) request from a target AN via a PCF network interface;
Send a UATI assignment of AT to the target AN through the PCF network interface,
And transmitted via the PCF network interface a request to establish a data connection of the same session to the PDSN supporting the session, and,
PCF via the network interface becomes the same HRPD packet data session of the active mode AT from support to Turkey Toto target PCF.

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